Structural proteins of La Crosse virus.

Preparations of La Crosse virus, a member of the California encephalitis group of bunyaviruses, were found to possess three major virion proteins. Two of the proteins were glycosylated (G1 and G2) and were located on the surface of the virus particles. These two glycoproteins were present in equimolar amounts and possessed apparent molecular weights of 120 X 10(3) and 34 X 10(3). Virion nucleocapsids, isolated by a nonionic detergent and salt treatment, contained another major protein, N (molecular weight = 23 X 10(3)). A large, but minor, protein species L (molecular weight = 180 X 10(3)) was also found in virus preparations. The approximate number of protein molecules per virion has been determined. Electron microscopy of purified La Crosse virus indicated that the virus particle (mean diameter, 91 nm) is enveloped and possesses irregular surface projections (length, 10 nm).     

Electron microscopy of vitrified-hydrated La Crosse virus.

La Crosse (LAC) virions were cryopreserved by rapid freezing in a thin layer of vitreous ice. The vitrified-hydrated LAC virions were subsequently imaged at -170 degrees C in a transmission electron microscope equipped with a low-temperature specimen holder. This cryoelectron microscopic technique eliminates the artifacts frequently associated with negative staining. Images of vitrified-hydrated LAC virions clearly revealed surface spikes as well as bilayer structure. Size measurements of the vitrified-hydrated LAC virions showed heterogeneity, with diameters ranging from 75 to 115 nm. Regardless of the particle size, the spike was about 10 nm long, and the bilayer was about 4 nm thick. The spikes are interpreted to be one or both of the glycoproteins, and the bilayer is interpreted to be the membrane envelope of the virus. In contrast to the pleomorphic appearance of the negatively stained LAC virions, the vitrified-hydrated LAC virions showed uniform spherical shapes regardless of their sizes.     

The ends of La Crosse virus genome and antigenome RNAs within nucleocapsids are base paired.

The three La Crosse virus genomes are found as circular structures in the electron microscope, and the RNA ends of at least the small (S) and medium (M) segments are highly complementary. When examined for psoralen cross-linking, about half of the S, at most 1 to 2% of the M, and none of the large (L) nucleocapsid RNAs could be cross-linked in virions or at late times intracellularly, under conditions in which each free RNA reacted completely. For the S segment, genomes and antigenomes first detected intracellularly could not be cross-linked at all, and their cross-linkability increased gradually with time. Antigenomes behaved similarly to genomes in all respects. It appears that the majority of all three segments are base paired at their ends and that the limited cross-linkability reflects the accessability of the RNA within nucleocapsids to psoralen. The gradual increase in cross-linkability may be important in persistent mosquito cell infection, in which it correlates with decreased S mRNA synthesis rates, and may be part of the mechanism which this infection becomes self-limiting. The implications of double-stranded RNA panhandles within nucleocapsids are discussed.     

Virulence of La Crosse virus is under polygenic control.

To identify which RNA segments of the California serogroup bunyaviruses determine virulence, we prepared reassortant viruses by coinfecting BHK-21 cells with two wild-type parents, La Crosse/original and Tahyna/181-57 viruses, which differed about 30,000-fold in virulence. The progeny clones were screened by polyacrylamide gel electrophoresis to ascertain the phenotype of the M and S RNA segments, and RNA-RNA hybridization was used to determine the genotype of selected clones. Two or three clones of each of the six possible reassortant genotypes were characterized quantitatively for neuroinvasiveness by determining the PFU/50% lethal dose (LD50) ratio after subcutaneous injection into suckling mice. The reassortants fell into two groups. (i) Six of seven reassortants with a La Crosse M RNA segment were as virulent as the parent La Crosse virus (about 1 PFU/LD50); the one exception was strikingly different (about 1,000 PFU/LD50) and probably represents a spontaneous mutant. (ii) The seven reassortants with a Tahyna M RNA segment were about 10-fold more virulent than the parent Tahyna virus (median 1,600 PFU/LD50 for reassortants and 16,000 PFU/LD50 for Tahyna virus). A comparative pathogenesis study in suckling mice of one reassortant virus and the parent Tahyna virus confirmed the greater neuroinvasiveness of the reassortant virus. From these data it was concluded that the M RNA segment was the major determinant of virulence, but that the other two gene segments could modulate the virulence of a nonneuroinvasive California serogroup virus.     

La Crosse virus infection of mammalian cells induces mRNA instability.

La Crosse virus infection of BHK cells leads to a dramatic shutoff of not only host protein synthesis but also viral protein synthesis later in infection. This shutoff can be accounted for by the loss of the cytoplasmic cellular and viral mRNAs. The induction of mRNA instability requires extensive virus replication, since when cycloheximide is added early in infection the preexisting viral and cellular mRNAs do not decrease upon incubation of the cultures. Pretreatment of the cultures with actinomycin D does not affect the ability of La Crosse virus infection to induce mRNA instability, and examination of the rRNAs shows no evidence of specific degradation due to activation of the interferon-associated latent RNase. The induction of mRNA instability therefore does not appear to operate through an interferon pathway. Viral mRNA synthesis, on the other hand, is not turned off during infection, and the cap-dependent endonuclease involved in viral mRNA initiation may be responsible for the mRNA instability.     

Nucleotide sequences at the terminal of La Crosse virus RNAs.

The 5' and 3'-terminal sequences of the three RNA molecules which make up the genomes of La Crosse virus are reported. Eleven nucleotides at both the 5' and 3' termini of all three RNAs are conserved and complementary. In addition more extensive unique sequence complementarity is present in at least two of the three RNAs.     

La Crosse virus production and export have a colchicine-sensitive step

In the present investigation, the effect of colchicine on La Crosse virus production and export was tested. Colchicine-treated, La Crosse virus-infected cells: (1) had decreased mean virus titers compared with those of control cells; (2) had a ratio of released to cell-associated virus of 1–1.9 whereas control cells had a ratio of 13. A colchicine-sensitive step, possibly involving microtubules, may be involved in virus production and/or release from the cell.     

La Crosse virus: replication in vertebrate and invertebrate hosts

La Crosse virus is maintained in a cycle involving mosquitoes and small mammals. Vertebrate cell infection is generally cytolytic; vector cell infection results in persistent infection. Features of La Crosse virus replication that may permit the virus to traffic between vector and vertebrate hosts and condition different infection outcomes are described.     

Anti-mRNAs in La Crosse bunyavirus-infected cells.

Unlike some members of the family Bunyaviridae which contain ambisense genomes, all La Crosse virus reading frames are translated from antigenome sense mRNAs. Nevertheless, La Crosse virus genome sense mRNAs or anti-mRNAs are initiated from antigenome templates. These are characterized by the same range of capped, nontemplated sequences at their 5' ends as mRNAs, but their 3' ends are presumed to be heterogenous, as they were not seen on RNA blots. The anti-mRNAs are estimated to be 15 to 30 times less abundant than mRNAs, but remarkably, this ratio is similar to that of functional genome sense mRNAs made from other bona fide ambisense segments. A role for these anti-mRNAs during infection is unclear.     

The translational requirement for complete La Crosse virus mRNA synthesis is cell-type dependent.

The translational requirement to prevent premature termination during La Crosse virus S mRNA synthesis was found to be cell-type dependent. This requirement was present in the BHK, HEL, and Vero cell lines we examined, but not in C6/36 mosquito cells. The cell-dependent translational requirement could be reproduced in vitro by using either cell extracts or purified virions of BHK and C6/36 cells. In the BHK reactions, the polymerase terminated predominantly at nucleotide 175 in the absence of concurrent translation and required translation to read through this position. In the C6/36 reactions, however, the polymerase reads through nucleotide 175 efficiently independent of translation. Reconstitution studies suggested that the translational requirement was due to a factor(s) present in BHK, but not in C6/36, cells.     

Recombination between snowhoe hare and La Crosse bunyaviruses.

We have previously reported heterologous genetic recombination resulting from crosses involving temperature-sensitive (ts) mutants of La Crosse (LAC) group II and snowshoe hare (SSH) group I ts mutants (J. Gentsch, L. R. Wynne, J. P. Clewley, R. E. Shope, and D. H. L. Bishop, J. Virol. 24:893-902, 1977). From those crosses two reassortant viruses having the large/medium/small viral RNA segment genotypes of SSH/LAC/SSH and SSH/LAC/LAC were obtained. In this study it has been found that the reciprocal cross (SSH group II x LAC group I ts mutants) has not yielded the expected LAC/SSH/SSH or LAC/SSH/LAC reassortant viruses. The backcross of a SSH/LAC/SSH group II ts mutant with a LAC group I ts mutant has produced a new reassortant virus, LAC/LAC/SSH, whereas the backcross of SSH/LAC/LAC group I ts mutants with SSH group II ts mutants gave another reassortant, SSH/SSH/LAC. Backcross analyses of LAC/LAC/SSH group I ts mutants with Group II ts mutants of SSH have not yielded the expected LAC/SSH/SSH reassortant virus, nor have backcrosses of SSH/SSH/LAC group II ts mutants with group I ts mutants of LAC virus yielded the expected LAC/SSH/LAC reassortant. Possible reasons why certain reassortant viruses are not produced are discussed. A procedure to screen SSH-LAC reassortant viruses which differ in their virion N polypeptides is described.     

Electron microscopy of the segmented RNA genome ofLa Crosse virus: absence of circular molecules.

The three species of single-stranded RNA present in La Crosse virus were examined in the electron microscope. Because large amounts of contaminating cellular DNA are copurified with the virus despite extensive attempts to purify the virus, it was necessary to use procedures that eliminated the bulk of this DNA before the viral RNA was analyzed. When this was done, the modal lengths of La Crosse virus RNA were 0.4, 2.0, and 3.1 mum. These lengths correspond well to their known molecular weights of 0.4 x 106, 1.8 x 106, and 2.9 x 106. Under the denaturing conditions used to permit complete spreading of these single-stranded RNA molecules, no single-stranded circular molecules are observed. Therefore, the circular nucleocapsids present in La Crosse virus and some other bunyaviruses do not appear to be due to convalent linkage of the ends of the RNA genome.     

Formation of recombinants between snowshoe hare and La Crosse bunyaviruses.

Wild-type recombinants were obtained at high frequency from coinfections of BHK cells involving temperature-sensitive, conditional-lethal mutants of snowshoe hare (SSH) and La Crosse (LAC) bunyaviruses. Analyses of two of the recombinants indicated that they have the genome compositions SSH/LAC/SSH and SSH/LAC/LAC for their respective L, M, and S virion RNA species. This evidence, together with that for the genetic stability of the recombinants, indicates that they were derived by segment reassortment of the competent genome pieces of the parental viruses. The SSH/LAC/SSH recombinant appears, from polypeptide analysis, to have the SSH type of nucleocapsid protein (N), whereas the SSH/LAC/LAC recombinant has the LAC nucleocapsid protein, suggesting that the viral S RNA codes for the N protein.